LEADER 01107nam0 22002891i 450 
001 UON00347511
005 20231205104326.783
010   $a03-334-5661-0
100   $a20091125d1988       |0itac50      ba
101   $aeng
102   $aGB
105   $a||||    1||||
200 1 $aPoems of W.B. Yeats$eA New Selection$fW.B. Yeats$gSelected, with an Introduction and Notes by A Norman Jeffares
205   $aSecond edition
210   $a London$cMacmillan Education$d1988
215   $axx, 428 p.$d22 cm.
620   $aGB$dLondon$3UONL003044
676   $a820.99415$cLetteratura inglese. Scrittori irlandesi$v21
700  1$aYEATS$bW.B.$3UONV119696$0152186
702  1$aJEFFARES$bA. Norman$3UONV108310
712   $aMacmillan Education$3UONV265683$4650
801   $aIT$bSOL$c20240220$gRICA
899   $aSIBA - SISTEMA BIBLIOTECARIO DI ATENEO$2UONSI
912   $aUON00347511
950   $aSIBA - SISTEMA BIBLIOTECARIO DI ATENEO$dSI Angl      VI A                    YEA         9                   $eSI LO 38532    5        9                   
996   $aPoems of W.B. Yeats$91359428
997   $aUNIOR

LEADER 05275nam  2201069z- 450 
001 9910557117303321
005 20210501
035   $a(CKB)5400000000040873
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/68538
035   $a(oapen)doab68538
035   $a(EXLCZ)995400000000040873
100   $a20202105d2021      |y         0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 00$aMultifunctional Composites
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2021
215   $a1 online resource (200 p.)
311 08$a3-0365-0492-3 
311 08$a3-0365-0493-1 
330   $aWith the progress in nanotechnology and associated production methods, composite materials are becoming lighter, cheaper, more durable, and more versatile. At present, great progress has been made in the design, preparation, and characterization of composite materials, making them smarter and versatile. By creating new properties using suitable fillers and matrix, functional composites can meet the most challenging standards of users, especially in high-tech industries. Advanced composites reinforced by high-performance carbon fibers and nanofillers are popular in the automotive and aerospace industries thanks to their significant advantages, such as high specific strength to weight ratio and noncorrosion properties. In addition to the improvement of the mechanical performance, composite materials today are designed to provide new functions dealing with antibacterial, self-cleaning, self-healing, super-hard, and solar reflective properties for desired end-use applications. On the other hand, composite materials can contribute to mitigating environmental issues by providing renewable energy technologies in conjunction with multifunctional, lightweight energy storage systems with high performance and noncorrosive properties. They are also used to prepare a new generation of batteries and directly contribute to H2 production or CO2 reduction in fuels and chemicals. This Special Issue aims to collect articles reporting on recent developments dealing with preparative methods, design, properties, structure, and characterization methods as well as promising applications of multifunctional composites. It covers potential applications in various areas, such as anticorrosion, photocatalyst, absorbers, superhydrophobic, self-cleaning, antifouling/antibacterial, renewable energy, energy storage systems, construction, and electronics. The modeling and simulation of processes involving the design and preparation of functional and multifunctional composites as well as experimental studies involving these composites are all covered in this Special Issue.
606   $aHistory of engineering and technology$2bicssc
610   $a3D printed coating
610   $a3D printing
610   $aABS
610   $aacrylic polyurethane coating
610   $aadsorption
610   $aannealing time
610   $aASA
610   $aattenuation
610   $abronze polylactic acid composite
610   $acarbon/carbon composites
610   $achitosan-pectin
610   $aco-precipitation
610   $acomposites
610   $acovalent biopolymer framework
610   $acrystallize process
610   $aCuO/ZnO
610   $acut fruits
610   $adoubly-curved shell and panel
610   $adye degradation
610   $aedible coating
610   $aenvironmental exposure
610   $aepoxidized Tung oil
610   $aFDM method
610   $afour-variable refined shell theory
610   $afree vibration analysis
610   $afunctionally graded carbon nanotube-reinforced composite (FG-CNTRC)
610   $amechanical properties
610   $amethylene blue
610   $amid-infrared spectroscopy
610   $amilk composition
610   $amilk optical and acoustical properties
610   $amilk spectral analysis
610   $amolecular dynamics
610   $amulti-material additive manufacturing
610   $amulti-phase coatings
610   $amultiphase polydisperse system
610   $an/a
610   $anano-composites
610   $anano-SiO2
610   $ananocomposite
610   $anatural fiber reinforced composites
610   $anear-infrared spectroscopy
610   $aNiAu alloy
610   $aoxidation resistance
610   $aphotocatalyst
610   $aphotodegradation
610   $apoly (lactic acid)
610   $apolyelectrolyte complex
610   $apost-harvest
610   $apulp fiber
610   $aquality
610   $aRaman spectroscopy
610   $aresponse surface method
610   $aspeed of sound
610   $astorage
610   $astrawberry
610   $astructure
610   $asunlight
610   $athermal cycling
610   $aultrasonic techniques
610   $aweathering resistance
615  7$aHistory of engineering and technology
700   $aNguyen-Tri$b Phuong$4edt$01302197
702   $aNguyen-Tri$b Phuong$4oth
906   $aBOOK
912   $a9910557117303321
996   $aMultifunctional Composites$93026238
997   $aUNINA